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Brain Science Advances 2020, 6(2): 106-119 https://doi.org/10.26599/BSA.2020.9050010
Review Article | Open Access | Issue | Published: 31 August 2020

Review of pathological index detection and new rehabilitation technique of drug addicts

Show Author's Information Banghua Yang1,§( ) Xuelin Gu1,§ Chao Gu2 Ding Xu3 Chengcheng Fan1
School of Mechanical and Electrical Engineering and Automation, Shanghai University, Shanghai 200444, China
Shanghai Qingdong Drug Rehabilitation Center, Shanghai 201701, China
Shanghai Drug Rehabilitation Administration, Shanghai 200080, China

§ These authors contributed equally to this work.

Keywords:
drug addiction, detoxification research, electro- encephalogram (EEG), near-infrared spectroscopy (NIRS), drug addiction rehabilitation
Cite this article:
Yang B, Gu X, Gu C, et al. Review of pathological index detection and new rehabilitation technique of drug addicts. Brain Science Advances, 2020, 6(2): 106-119. https://doi.org/10.26599/BSA.2020.9050010
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Abstract Full text About this article

There are two major research issues with regard to detoxification; one is pathological testing of drug users and the other is rehabilitation methods and techniques. Over the years, domestic and foreign researchers have done a lot of work on pathological changes in the brain and rehabilitation techniques for drug users. This article discusses the research status of these two aspects. At present, the evaluation of brain function in drug addicts is still dominated by a single electroencephalography (EEG), near- infrared spectroscopy (NIRS), or magnetic resonance imaging scan. The multimodal physiological data acquisition method based on EEG–NIRS technique is relatively advantageous for actual physiological data acquisition. The traditional drug rehabilitation method is based on medication and psychological counseling. In recent years, psychological correction (e.g., emotional ventilation, intelligent physical and mental decompression, virtual reality technique and drug addiction suppression system, sports training, and rehabilitation) and physical therapy (transcranial magnetic stimulation) have gradually spread. These rehabilitations focus on comprehensive treatment from the psychological and physical aspects. In recent years, new intervention ideas such as brain–computer interface technique have been continuously proposed. In this review, we have introduced multimodal brain function detection and rehabilitation intervention, which have theoretical and practical significance in drug rehabilitation research.


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About this article

Review of pathological index detection and new rehabilitation technique of drug addicts

Show Author's information Banghua Yang1,§( )Xuelin Gu1,§Chao Gu2Ding Xu3Chengcheng Fan1
School of Mechanical and Electrical Engineering and Automation, Shanghai University, Shanghai 200444, China
Shanghai Qingdong Drug Rehabilitation Center, Shanghai 201701, China
Shanghai Drug Rehabilitation Administration, Shanghai 200080, China

§ These authors contributed equally to this work.

Abstract

There are two major research issues with regard to detoxification; one is pathological testing of drug users and the other is rehabilitation methods and techniques. Over the years, domestic and foreign researchers have done a lot of work on pathological changes in the brain and rehabilitation techniques for drug users. This article discusses the research status of these two aspects. At present, the evaluation of brain function in drug addicts is still dominated by a single electroencephalography (EEG), near- infrared spectroscopy (NIRS), or magnetic resonance imaging scan. The multimodal physiological data acquisition method based on EEG–NIRS technique is relatively advantageous for actual physiological data acquisition. The traditional drug rehabilitation method is based on medication and psychological counseling. In recent years, psychological correction (e.g., emotional ventilation, intelligent physical and mental decompression, virtual reality technique and drug addiction suppression system, sports training, and rehabilitation) and physical therapy (transcranial magnetic stimulation) have gradually spread. These rehabilitations focus on comprehensive treatment from the psychological and physical aspects. In recent years, new intervention ideas such as brain–computer interface technique have been continuously proposed. In this review, we have introduced multimodal brain function detection and rehabilitation intervention, which have theoretical and practical significance in drug rehabilitation research.

Keywords: drug addiction, detoxification research, electro- encephalogram (EEG), near-infrared spectroscopy (NIRS), drug addiction rehabilitation

References(42)

[1]
ND Volkow, JS Fowler, GJ Wang. The addicted human brain: insights from imaging studies. J Clin Invest. 2003, 111(10): 1444-1451.
Google Scholar
[2]
TB Baker, ME Piper, DE McCarthy, et al. Addiction motivation reformulated: an affective processing model of negative reinforcement. Psychol Rev. 2004, 111(1): 33-51.
Google Scholar
[3]
A Wikler. Recent progress in research on the neurophysiologic basis of morphine addiction. Am J Psychiatry. 1948, 105(5): 329-338.
Google Scholar
[4]
DJ Drobes, ST Tiffany. Induction of smoking urge through imaginal and in vivo procedures: physiological and self-report manifestations. J Abnorm Psychol. 1997, 106(1): 15-25.
Google Scholar
[5]
MA Sayette, CS Martin, MA Perrott, et al. A test of the appraisal-disruption model of alcohol and stress. J Stud Alcohol. 2001, 62(2): 247-256.
Google Scholar
[6]
D Zhu, GB Dai, D Xu, et al. Long-term effects of Tai Chi intervention on sleep and mental health of female individuals with dependence on amphetamine-type stimulants. Front Psychol. 2018, 9: 1476.
Google Scholar
[7]
K Wang, J Luo, TR Zhang, et al. Relationship between drug addiction and dopaminergic neurons—Regulation of resistance movement (in Chinese). Chin J Drug Depend. 2019, 28(4): 254-262.
Google Scholar
[8]
K Zhang, HF Jiang, QY Zhang, et al. Brain-derived neurotrophic factor serum levels in heroin-dependent patients after 26 weeks of withdrawal. Compr Psychiatry. 2016, 65: 150-155.
Google Scholar
[9]
HF Jiang, J Du, F Wu, et al. Efficacy of contingency management in improving retention and compliance to methadone maintenance treatment: a random controlled study (in Chinese). Shanghai Arch Psychiatry. 2012, 24(1): 11-19.
Google Scholar
[10]
WZ Wang, HF Jiang, M Zhao. Current situation of psychoactive prescription drug abuse (in Chinese). Chin J Drug Depend, 2019, 28(3):178-182.
Google Scholar
[11]
LY Zhao, XL Zhang, J Shi, et al. Psychosocial stress after reactivation of drug-related memory impairs later recall in abstinent heroin addicts. Psychopharmacology (Berl). 2009, 203(3): 599-608.
Google Scholar
[12]
J Shi, LY Zhao, ML Copersino, et al. PET imaging of dopamine transporter and drug craving during methadone maintenance treatment and after prolonged abstinence in heroin users. Eur J Pharmacol. 2008, 579(1/2/3): 160-166.
Google Scholar
[13]
SX Li, J Li, DH Epstein, et al. Serum cortisol secretion during heroin abstinence is elevated only nocturnally. Am J Drug Alcohol Abuse. 2008, 34(3): 321-328.
Google Scholar
[14]
LA Tuscan, JD Herbert, EM Forman, et al. Exploring frontal asymmetry using functional near-infrared spectroscopy: a preliminary study of the effects of social anxiety during interaction and performance tasks. Brain Imaging Behav. 2013, 7(2): 140-153.
Google Scholar
[15]
Z Yong, C Bin, L Dong. A three-dimensional geometric Monte Carlo method for simulation of light propagation in biological tissues (in Chinese). Chin J Lasers. 2015, 42(1): 0104003.
Google Scholar
[16]
CY Wu, QP Lu, HQ Ding, et al. Noninvasive blood glucose sensing with near-infrared spectroscopy based on interstitial fluid (in Chinese). Acta Opt Sin. 2013, 33(11): 1117001.
Google Scholar
[17]
F Wallois, M Mahmoudzadeh, A Patil, et al. Usefulness of simultaneous EEG–NIRS recording in language studies. Brain Lang. 2012, 121(2): 110-123.
Google Scholar
[18]
F Wallois, A Patil, C Héberlé, et al. EEG–NIRS in epilepsy in children and neonates. Neurophysiol Clin. 2010, 40(5/6): 281-292.
Google Scholar
[19]
P Pouliot, TP Tran, V Birca, et al. Hemodynamic changes during posterior epilepsies: an EEG-fNIRS study. Epilepsy Res. 2014, 108(5): 883-890.
Google Scholar
[20]
A Dutta, A Jacob, SR Chowdhury, et al. EEG–NIRS based assessment of neurovascular coupling during anodal transcranial direct current stimulation—A stroke case series. J Med Syst. 2015, 39(4): 205.
Google Scholar
[21]
U Jindal, M Sood, A Dutta, et al. Development of point of care testing device for neurovascular coupling from simultaneous recording of EEG and NIRS during anodal transcranial direct current stimulation. IEEE J Transl Eng Health Med. 2015, 3: 2000112.
Google Scholar
[22]
B Chance, MB Maris, J Sorge, et al. Phase modulation system for dual wavelength difference spectroscopy of haemoglobin deoxygenation in tissue. Proc Spie. 1990, 1204: 481-491.
Google Scholar
[23]
K Isobe, T Kusaka, K Nagano, et al. Functional imaging of the brain in sedated newborn infants using near infrared topography during passive knee movement. Neurosci Lett. 2001, 299(3): 221-224.
Google Scholar
[24]
AM Chiarelli, F Zappasodi, F Di Pompeo, et al. Simultaneous functional near-infrared spectroscopy and electroencephalography for monitoring of human brain activity and oxygenation: A review. Neurophotonics. 2017, 4(4): 041411.
Google Scholar
[25]
F Al-Shargie, TB Tang, M Kiguchi. Assessment of mental stress effects on prefrontal cortical activities using canonical correlation analysis: An fNIRS-EEG study. Biomed Opt Express. 2017, 8(5): 2583-2598.
Google Scholar
[26]
B Abibullaev, J An, SH Lee, et al. Design and evaluation of action observation and motor imagery based BCIs using near-infrared spectroscopy. Measurement. 2017, 98: 250-261.
Google Scholar
[27]
A Kassab, J Le Lan, J Tremblay, et al. Multichannel wearable fNIRS-EEG system for long-term clinical monitoring. Hum Brain Mapp. 2018, 39(1): 7-23.
Google Scholar
[28]
A von Luhmann, J Addesa, S Chandra, et al. Neural interfacing non-invasive brain stimulation with NIRS-EEG joint imaging for closed-loop control of neuroenergetics in ischemic stroke. In 2017 8th International IEEE/EMBS Conference on Neural Engineering (NER). Shanghai, China, 2017.
[29]
MP Paulus, NE Hozack, BE Zauscher, et al. Behavioral and functional neuroimaging evidence for prefrontal dysfunction in methamphetamine- dependent subjects. Neuropsychopharmacol. 2002, 26(1): 53-63.
Google Scholar
[30]
AC Dieler, MM Plichta, T Dresler, et al. Suppression of emotional words in the Think/No-Think paradigm investigated with functional near-infrared spectroscopy. Int J Psychophysiol. 2010, 78(2): 129-135.
Google Scholar
[31]
LD Zhou, XJ Chen, CG Wang, et al. Progress in treatment on substance use disorders with virtual reality technologies (in Chinese). Chin Sci Bull. 2017, 62(9): 888-896.
Google Scholar
[32]
HP Wang, ZW Sun, FL Wei, et al. Effects of aerobic exercise on physical fitness and mental behavior in patients with drug dependence: A meta analysis (in Chinese). Chin J Drug Depend. 2019, 28(2): 126-134.
Google Scholar
[33]
DS Wang, CL Zhou, YK Chang. Acute exercise ameliorates craving and inhibitory deficits in methamphetamine: An ERP study. Physiol Behav. 2015, 147: 38-46.
Google Scholar
[34]
DS Wang, CL Zhou, M Zhao, et al. Dose-response relationships between exercise intensity, cravings, and inhibitory control in methamphetamine dependence: An ERPs study. Drug Alcohol Depend. 2016, 161: 331-339.
Google Scholar
[35]
YH Zhou, M Zhao, CL Zhou, et al. Sex differences in drug addiction and response to exercise intervention: From human to animal studies. Front Neuroendocrinol. 2016, 40: 24-41.
Google Scholar
[36]
H Pareja-Galeano, F Sanchis-Gomar, S Mayero. Exercise as an adjuvant intervention in opiate dependence. Subst Abus. 2013, 34(2): 87-88.
Google Scholar
[37]
MS Buchowski, NN Meade, E Charboneau, et al. Aerobic exercise training reduces cannabis craving and use in non-treatment seeking cannabis-dependent adults. PLoS One. 2011, 6(3): e17465.
Google Scholar
[38]
J Benos, K Kapinas. EEG examination in heroin addicts in rehabilitation. Med Welt. 1980, 31(39): 1395-1399.
Google Scholar
[39]
A Olivennes, A Charles-Nicolas, C Olievenstein. Changes in the waking electroencephalogram in severe heroin addiction. Ann Med Psychol. 1983, 141(4): 458-469.
Google Scholar
[40]
AB Gekht, AG Polunina, EA Briun, et al. Brain bioelectrical activities in heroin addicts during early abstinence period (in Russian). Zh Nevrol Psikhiatr Im S S Korsakova. 2002, 103(5): 53-59.
Google Scholar
[41]
WC Zhang, CQ Tan, FC Sun, et al. A review of EEG-based brain-computer interface systems design. Brain Sci Adv. 2018, 4(2): 156-167.
Google Scholar
[42]
C Liu, FC Sun, B Zhang. Brain-inspired multimodal learning based on neural networks. Brain Sci Adv. 2018, 4(1): 61-72.
Google Scholar
Publication history
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Publication history

Received: 14 February 2020
Revised: 25 March 2020
Accepted: 27 March 2020
Published: 31 August 2020
Issue date: June 2020

Copyright

© The authors 2020

Acknowledgements

The authors thank the Shanghai Drug Rehabilitation Administration and Shanghai Qingdong Drug Rehabilitation Center for their support, and all the people who contribute to the writing of the article.

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This article is published with open access at journals.sagepub.com/home/BSA

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